DE7506584U - DRILLING TOOL WITH DRILL AND ADAPTER - Google Patents

Description

15 IT * J. Mir · 1975

HILTI AKTIENGESELLSCHAFT IN SCHAAN (Principality of Liechtenstein)

Drilling tool with drill and receiving part

The invention relates to a drilling tool with a drill and a sleeve-like receiving part comprising the drill shank, wherein the jacket of the receiving part is at least partially made of a material that is larger than the material of the receiving part There is thermal conductivity.

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In known drilling tools, the working part is mostly and the receiving part made in one piece from the same material. While the receiving part is on the drill in which the respective drilling tool is used, coordinated dimensions, essentially constant for each type of drilling machine has, the working part of the drilling tool can vary in its dimensions depending on the requirements. Particularly with small drill dimensions, there are considerable differences in diameter, which must be balanced between the working part and the receiving part.

To compensate for these dimensional differences, it is known to either correspond to the diameter of the working part To upset the starting material so that the desired receiving part can be worked on or the diameter the starting material corresponding to the receiving part by material removal or reshaping to the diameter of the working part to work. It is also known to use starting material of an average diameter and to work this through a combination of the mentioned working methods to the desired dimensions.

In view of the large amounts of material to be reshaped, these known methods are relatively uneconomical and therefore very expensive manufacturing methods. Also joining the parts with large differences in diameter Soldering or welding could not fix all the disadvantages, especially because the big one Weight of the drilling tools manufactured according to the methods mentioned has a detrimental effect.

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In order to remedy these known disadvantages, attempts have been made, working part and to manufacture the receiving part of drilling tools from two parts and to connect them to one another, that is to say the To provide the shaft of the drill with a sleeve-like receiving part made of a different, cheaper material. In particular it has been shown that materials which are softer than the material of the working part can be used for the receiving part, particularly proven, since a drilling tool with such a receiving part is favorable due to the damping properties affects the drill. These known tools, which are preferably used in rotary hammers, are mostly designed so that the drill shank completely penetrates the receiving part axially, so that the acting in the axial direction, blows generated by the hammer drill ^ directly on the shaft of the drill and the rotary motion of the hammer drill is transferred to the drill shank via the softer receiving part. A connection is required between the receiving part and the drill shank, which allows the torque to be transmitted Withstands. This requirement can be met relatively well, for example, with a receiving part made of plastic.

In these known drilling tools that can be produced more economically however, the poor thermal conductivity of the material used for the receiving part has proven to be considerable proved disadvantageous.

It is known that the friction of the drilling tool in the borehole causes considerable heating. In addition, it will Drilling tool also at its rear end when used in rotary hammers due to the impacts quite considerably warmed up. This heat, which in the one-piece

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Drilling tools on the recordings of the rotary hammers was derived, can with a receiving part made of a material with are no longer degraded compared to the working part of lower thermal conductivity. Rather, the heat builds up in the drill shank, so that undesirable deformations occur, for example, in a receiving part made of plastic can, and thus sufficient transmission of the torque from the receiving part to the drill shank and the centering of the drill shank in the receiving part is no longer guaranteed is. In addition, the accumulated heat causes the receiving part to expand so that between The receiving part and the receiving part of the hammer drill create an undesirable friction, which leads to a further increase in temperature Consequence. This is the game between the receiving part and the recording of the necessary for proper function Hammer drill no longer ensured.

The present invention is based on the problem of an economical and unproblematic one with regard to the dissipation of heat producible to create drilling tool.

According to the invention, the object is achieved in that the drill shank is made of a material via heat-conducting bridges compared to the material of the receiving part greater thermal conductivity with the jacket of the receiving part communicates.

Such heat conduction bridges, which can be embedded in the material of the receiving part, bring about a sufficient Dissipation of the resulting heat from the drill shank to the jacket of the receiving part, with the jacket of the receiving part the heat is dissipated to the intake of the drilling machines. This means that at least parts of the jacket of the receiving part consist of a material which compared to the

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remaining material of the receiving part a larger one

\ Has thermal conductivity. It is possible to use the receiving part

] to encase completely with such a material or only

partially enforce the jacket with parts made of such material. They can also be attached to the outer surface of the receiving part protruding parts of the heat conducting bridges which form the matel parts with greater thermal conductivity.

The receiving part can have any shape. Nabst a receiving part with thread can have any cross-sectional shapes, such as multi-cariprofiles, polygon-like Profiles, spline profiles and such forms of training are used.

In particular, for reasons of proper heat transfer, it is advisable to use the heat-conducting bridges as one piece the matel parts made of a material with a greater thermal conductivity than the material of the receiving part To train webs. This preferred embodiment can, as mentioned, for example by up to the surface of the Receiving part protruding thermal bridges are met. Another possibility is to use the receiving part with a jacket made of a material with high thermal conductivity, on which the heat conducting bridges designed as webs are formed, to be connected. For example at the use of plastic as the material for the receiving part, the jacket can be prefabricated with greater thermal conductivity and then injected with the plastic, with a final shape of the jacket of the receiving part is still possible after spraying.

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Preferably, the drill shaft is constructed as a veibunden with the Wärmeieitbrücken webs for proper transmission of torque and to ensure sufficient heat transfer. This connection can be made, for example, by plunging the webs into prefabricated recesses on the drill shank, or a connection can be established between the webs and the drill shank by means of welding or soldering.

A connection between the drill shank and the heat conducting bridges designed as webs can expediently take place by means of a sleeve surrounding the drill shaft which is connected in one piece to the webs. This sleeve can in turn be connected to the drill shank in various ways, for example soldering, welding or plunging onto raised areas or depressions in the drill shank.

According to a further proposal of the invention, the Thermally conductive bridges as radially surrounding the drill shaft and penetrating the material of the receiving part and disks projecting up to the jacket thereof can be formed. The production of such a receiving part, which in particular has good properties in terms of strength, can be carried out, for example, by overmolding with plastic, whereby it is expedient to have the disks with openings or the like to provide an optimal connection with the plastic.

For example, in the case of a receiving part provided with a thread, it is expedient to use the heat-conducting bridges as one of the drill shank to form surrounding and the material of the receiving part penetrating helix. A preferred manufacture of one Such a trained receiving part can be done in that a thread is prefabricated on the drill shank, on which

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the helix is applied with a corresponding pitch. Then the material of the receiving part, which is made of plastic, for example, can be applied by overmolding , whereby it is again expedient for the connection between the plastic and the helix to use the latter; ' Breakthroughs or the like to be attached. This embodiment has in particular, the advantage that a purely mechanical Reinforcement of the most heavily stressed part of the receiving part, that is to say in the present case the thread, takes place.

The invention will now be explained in more detail with reference to drawings showing them for example and although show:

1 shows a drilling tool with a receiving part shown in section

2 shows a section along the line II - II

Fig. 3 is a cross section through a drill shaft with a polygonal shaped receiving part

4 shows a drill shank with a receiving part shown in longitudinal section

Fig. 5 shows another embodiment of a

Drill shank with the receiving part shown in longitudinal section

From Fig. 1, a drilling tool is shown with a total of 1 x drill designated and a receiving part, generally designated 2. The working part 3 of the drill

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Is designed in the usual way, for example as a spiral part. The drill shank 4 is surrounded by the receiving part 2, which, as in particular Flg. 2 shows a hexagonal Has outer contour. The receiving part 2 consists of a base body made, for example, of plastic 5 and a thermal bridge 6 together. As FIGS. 1 and 2 show by way of example, there is a heat conducting bridge 6 from a sleeve 6a surrounding the drill shank 4 and one part of the jacket of the receiving part 2 forming sleeve 6b, v / above the sleeves 6a, 6b are connected to one another via a flange-axed web 6c. The bridge 6c has openings 6d to improve the connection with the base body 5.

The embodiment shown by way of example according to FIGS. 1 and 2 a heat conduction bridge is not limited to use in multi-edged receiving parts, but can be used for any other cross-sectional shape. The attachment of the thermal bridges on the drill shank 4 can also take place in any desired manner, in particular by form-fitting, welding, soldering or similar.

Figure 3 shows an embodiment in which a total with 8 designated receiving part is positively connected to a drill shank 9. The receiving part 8 consists from a base body 10, which is surrounded by a sleeve 11, on which webs 11a are integrally formed. The bridges 11a of the sleeve 11 protrude into corresponding recesses 9a of the drill shank 9, so that between the receiving part 8 and Drill shank 9 a positive connection is made.

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Again, this embodiment is shown only by way of example i, jt not only on a receiving part with a polygonal cross-section, as shown in FIG. 3, limit it, but leave it can be used for receiving parts with any cross-section. The production of such a receiving part can ι, 'for example by injecting the between the drill shank 9

and sleeve 11 existing cavity with plastic and subsequent The webs 11a are requested.

^{FIG. 4 shows a drill shank 12 with a receptacle r} : p 'part which has an external thread and is designated as a whole by 13. The heat conduction bridges are in this embodiment ^; ? play formed as a helix 14, which parts of the jacket

of the receiving part 13 forms. The manufacture of one of the

! like receiving part can be done in that the helix

i; ^: 14 on the drill shaft with a thread 15. 12 put on

s; is, and then the drill shank 12, for example with plastic

1 | substance is overmolded. To improve the connection between

sprayed-on material and helix, can in the latter through-> fractions 16 be arranged.

FIG. 5 shows a drill shank 17 with a receiving part designated overall by 18, which has heat conducting bridges designed as disks 19, which form part of the jacket of the receiving part 18. Such a receiving part can in turn be produced by injection molding around the drill shank 17 with plastic after the disks 19 _{f have been applied} . To improve the connection between the overmolded material and disks 19, these can in turn be provided with openings 20. To fix the disks 19; Various possibilities are available on the drill shank 17, for example soldering, welding or a connection of the two parts by means of a form fit by appropriate shaping of the interlocking parts.

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Claims (7)

(jn proverbs X It Bohrwerkaeug with drill and a drill shaft encompassing sleeve-like receiving part, the jacket of the receiving part at least partially made of a material of greater than the material of the receiving part There is thermal conductivity, characterized in that the drill shank (4, 9, 12, 17) via thermal conduction bridges, made of a material with a greater thermal conductivity than the material of the receiving part (2, 8, 13, 18), is in communication with the jacket of the receiving part (2, 8, 13, 18). 2. Tool according to claim 1, characterized in that the heat-conducting bridges as webs that are integrally connected to the jacket parts with greater thermal conductivity (6c, Ha) are trained. 3. Tool according to claim 2, characterized in that the webs (6c, Ha) are connected to the drill shank (4, 9) are. 4. Tool according to claim 2, characterized in that the webs (6c) are integral with one of the drill shank (4) surrounding sleeve (6a) are connected. 5. Tool according to claim 4, characterized in that the sleeve (6a) is connected to the drill shank (4). 6. Tool according to claim 1, characterized in that the heat conducting bridges of, the receiving part (18) penetrating, Disks (19) are formed. 7. Tool according to claim 1, characterized in that the heat conduction bridges of one, the receiving part (13) penetrating, helix (14) are formed. 7506584 23.1176